Compositions of matter containing glycidyl ethers and oxalic acid



Patented Mar. .14, 1950 COMPOSITIONS OF MATTER CONTAINING GLYCIDYL ETHERS AND OXALIC ACID Theodore F. Bradley, Oakland, Calif., assignor to Shell Development Company, San Francisco, Calif., a corporation of Delaware No Drawing. Application March 29, 1948,

. Serial No. 17,798 I 11 Claims. 1

This invention relates to compositions of matter which are heat curable to valuable materials and are useful in the manufacture of varnishes, enamels, molding compositions, adhesives, films, fibers, molded articles, etc. More particularly, the invention is concerned with reacting and curing of glycidyl ethers to resinous products with oxalic acid whereb especially advantageous results are obtained.

According to the present invention, an ether containing glycidyl groups so as to have an epoxy equivalency greater than one is mixed and reacted with oxalic acid. The glycidyl ethers contained in the compositions of the invention have at least six carbon atoms and one or more ethereal oxygen atoms. In order that the composition will cure by reaction with the oxalic acid into material of high molecular weight and resinous character, the glycidyl ether has a 1,2- epoxy equivalency which is greater than one. By the epoxy equivalency, reference is made to the average number of 1,2-epoxy groups contained in the average molecule of the ether. In the case 'where a substantially pure, simple compound is used, the epoxy equivalency will be an integer of two or more. For example, the

' epoxy equivalency of diglycidyl ether, or of the diglycidyl ether of ethylene glycol is two,-while that of the triglycidyl ether of glycerol is three. However, the glycidyl ether may be a mixture of chemical compounds which, although they are of similar identity and chemical constitution, have different molecular weights. The measured molecular weight of the mixture, upon which the epoxy equivalency is dependent, will 'necessarily be an average molecular weight.-

' an epoxy equivalency of about 1.34-i. e., an

average of about 1.34-epoxy groups per molecule.

The glycidyl ethers used in the invention preferably contain only the elements carbon, hydrogen and oxygen. They include 1,2-epoxycontaining polyethers of polyhydric alcohols such as polyglycidyl ethers thereof like diglycidyl ether of ethylene glycol, propylene glycol, trimethylene glycol, butylene glycol, diethylene glycol, triethylene glycol, glycerol, .dipropylene glycol and the like. class include glycidyl ethers of polyhydric alcohols having a 1,2-epoxy equivalency greater than one such as the polyglycidyl ethers of glycerol, diglycerol, erythritol, pentaglycerol, pentaerythritol, mannitol, sorbitol, polyallyl alcohol, polyvinyl alcohol and the like. The polyglycidyl polyethers of the polyhydric alcohols are prepared by reacting the polyhydric alcohol with epichlorohydrin in the presence of 0.1 to about 2% of an acid-acting compound as catalyst such as boron trifluoride, hydrofluoric acid or stannic chloride whereby the chlorhydrin ether is formed as product. The reaction is effected at about 50 C. to C. with the proportions of reactants being such that there is about one mol of epichlorhydrin for each molecular equivalent of hydroxyl group in the polyhydric alcohol. Thus, in preparing the ether of diethylene glycol, which glycol contains two hydroxyl groups in each molecule thereof, about two mols of epichlorhydrin for each mol of diethylene glycol are used. The resulting chlorhydrin ether from the reaction of a polyhydric alcohol with epichlorhydrin is dehydrochlorinated by heating at about 50 C. to 125 C. with a small, say 10%, stoichiometrical excess of a base. For this purpose, sodium aluminate gives good results.

Preparation of the polyglycidyl ethers of the polyhydric alcohols may be illustrated by considering application of the foregoing method in preparing the glycidyl ether of glycerol. In parts by weight, about 276 parts of glycerol (3 mols) are mixed with 828 parts of epichlorhydrin (9 mols). To this reaction mixture are added 10 parts of a diethyl ether solution containing about 4.5% of boron trifluoride. The temperature rises Other typical ethers of this as a result of the exothermic reaction and external cooling with ice water is applied so as to keep the temperature between about 50 C. and 1 75 C. during a reaction period of about 3 hours.

I the reactionproduct is washed with water until free of base. Although the product isa complex may be represented by the formula mixture of glycidyl ethers, the principal product About 370 parts or the resulting glycerol-epichlorhydrin condensate are dissolved in 900 parts'ot dioxane containing about 300 partsofsodium aluminate. while agitating, the reaction mixture is heated and refluxed at 93 C. forabout 9 hours.

After cooling to atmospheric temperature, them mixture and low bolling substances' removed by, distillation to a temperature of 205 C. at 20 mm. 7

insoluble material is filtered from the reaction pressure. The epox'yether, in amount-of 261 parts, isa pale yellow, viscous liquid." It has an 1 epoxide value of 0.671 equivalent per 100 grams and themolecular weight 19.324 as measured ebulloscopically in a dioxane solution. 7 values show that the glycidyl ether has an epoxy equivalency 218,1. ,e., an average of 2.18 epox- These ide groups per molecule.

The 1,2-epoxide value of theglycidyl ether is 1 determined by heating a one gram sample of the ether with an excess of pyridinium chloride dissolved in' pyridine (made by adding pyridine to.

16 cc..of concentrated hydrochloricacid toa total volume 'of one liter) at the boiling point for 20 minutes whereby the pyridinium chloride hydrochlorinates the epoxy groups to chlorhydrin groups. I backtitrated with 0.1 N sodium hydroxideto the The excess pyridinium chloride-is then phenolphthalein end point. The epoxide value is calculated by considering one HCl as equivalent to one epoxide group. This method is used for obtaining all the epoxide values discussedv herein.

A preferred group of epoxy ethers with which oxalic acid reacts with particular advantage to like resorcinol, catechol, hydroquinone, .'etc., or .polynuclear phenols like bis-(e hydroxyphenyl) v 4,4'-dihydroxy' benzo- 2,2-propane (bisphenol) P ydr yphenyi -1,1fethane, bis-' 7 (4 -Yhydroxyphenyl) 1,1 isobutane; bis- (4 -hydroxyphenyl) 2,2 butane, bis (4 {hydroxy -2-' methylphenyl) -2,2-propane, bis 4-hydroxy -2- tertiary butyl phenyl)-2,2-propane, bis-(z-dihydroxynaphthyl) -methane,- 1,5-dihydroxy naph-" thalene, etc. The glycidyl ethers of the dihydric phenols are made by heating at 50 C. to 150 C. the dihydric phenolwith epichlorhydrin, using one to two or more mols of epichlorhydrin per mol of the dihydric phenol. Also present is a base such as sodi- 1 .umypotassium, calcium or barium hydroxide in .famount of 10'to 30% stoichiometric excess of the epichloryhdrini. e,, 1.1 to 1.3 equivalents of base per mol of epichlorhydrin. The heating is continued for several hours to convertthereac- 1 tion mixture to a tafly-like consistency whereupon 'hydrin per mol of dihydric alcohol from about two' the softening point of the resinous glycidyl ether is increased. In general, these glycidyl ethers, having an epoxy equivalency between one and two, contain terminal 1,2-epoxy groups, and have 1 alternate aliphatic and aromatic 'groups' linked together by' ethereal oxygen atoms.

The nature or the gycidyl ethers from dihydric phenols can be better understood by considering preparation of a particular product which I prefer to use in my invention. This product will hereinafter be designated by the'term Resin A.

RESINA lIn a'reaction vessel fitted with a stirrer, 4 mols ofv bis-(4-hydroxphenyl)-2,2 propane (bisphenol) and 5 mols of epichlorhydrin are added to- 6.43 mols of sodium hydroxide as a 10% aqueous I solution. While being stirred, the reaction mixture is gradually heated to about 100 C. during 80 minutes time and is maintained at 100-104 C. for an additional 60 minutes under reflux. The aqueous layer is decanted and the resin washed with boiling water until neutral-to litmus wheredehydrated by upon the resin is drained and heating to about 150 C.

' The resulting resinous glycidyl-ether has a softening point of 100 C. (Durrans Mercury Method) and a molecular weight of'1133 measured by boiling point elevation of a dioxane solution. The epoxide value is 0.116 equivalent per' 100 grams so the epoxide equivalency is 1.32 epoxide groups per molecule.

In like manner, other resinous glycidyl ethers of bis-'phenol'may be prepared which will have dif'! ferent molecular weights depending upon the molar ratio of epichloryhdrin to dihydric phenol used in preparation thereof. 1 This fact is illustrated by the following table which shows the 55 variation in -properties with variation in the e molar ration. 3 I

MolR atio MolRaiio Equiv. 1lliiliicflo'r- 112312103 10 g Mvglecllillar Epoxy gggg y rm 0 pic: oreig t per bis-Phenol hydrin Pmnt l00gn1s. per M01.

00 2.15 1.1 e 43 451 0.318 1.39 1.4 V 1.3 84 791- 0.100 1.34 1.33- 1.3 802 0.137. 1.10 as 1 1.25 1. a 1, 133 0.110 1. 32 1.2 1.3 112 1,420 0. 0R5 1.21

Resin A.

These glycidyl ethers from bis-phenol are a 70 complex mixture of compounds believed to have as the principal component thereof a substance which may be represented by the formula wherein R represents the divalent hydrocarbon radical of the dihydric phenol and at is an integer. or the series 0, 1, 2, 3, etc. The length of the.

chain can be made to vary by changing the molec-- qular proportion of epichlorhydrin and. dihydric phenol. Thus by decreasing themols of epichlordownwards toward one, the moceular weight and Y etc. It may be noted that the observed molecular weight and epoxy value are probably ,low due to inherent inaccuracies of the methods of determining the values. The determined epoxy value appears to be only about 60% of the theoretical value, but in any event the epoxy equivalency is greater than one and the resinous glycidyl ethers cure to hard, tough, insoluble and infusible resins upon heating with oxalic acid.

The composition of the invention comprises 1) a glycidyl ether having a 1,2-epoxy equivalency greater than one, and (2) oxalic acid. The relative amounts of the two essential components of the composition may be varied. There may be used approximately an equivalent amount of oxalic acid-i. e., such an amount that there is one carboxylic acid group for each 1,2-epoxy group in the ether. For example, when diglycidyl ether is used with oxalic acid, the ether has an epoxy value of about 1.54 equivalents of epoxy per 100 grams and the oxalic acid has an acid value of about 2.22 equivalents of acid per 100 grams so there may be used about 69 parts by weight of the acid with each 100 parts by weight of the ether. Likewise, when the glycidyl ether of bis-phenol is used such as Resin A havin an epoxy value of about 0.116 equivalent of epoxy per 100 grams, th composition may contain about 5.2 parts by weight of oxalic acid for each 100 parts of the glycidyl ether.

The oxalic acid used as curing agent in the composition of the invention is ordinarily added to the glycidyl ether as oxalic acid dihydrate, which form is commercially available. Oxalic acid dihydrate contains two molecules of water of crystallization and has an acid equivalency of 1.59 per 100 grams. When using equivalent amounts of oxalic acid dihydrate with the aboveexemplified ethers, there would be employed 97 grams of the dihydrate per 100 grams of diglycidyl ether and 7.3 grams per 100 grams of Resin A.

The proportion of oxalic acid used in the composition of the invention may vary over wide limits. Good results with curing to infusible products are obtained when 60% to 170% of the equivalent amount of acid is used. Ordinarily it is preferred to use a small excess over the equivalent amount of acid such as about 110% to 160% of the equivalent amount since optimum cures appear to be obtained with about 150% of the equivalent amount of acid. If desired, however, proportions from about 5% to 300% of the equivalent amount may be used, or even higher or lower percentages.

The compositions of the invention are best reacted on cured by heating at a temperature of 50 C. to 250 C. At the lower portion of the range, the rate of reaction is somewhat slow, but by operating at a preferred temperature of 125 C. to 175 C., the reaction is complete in from about minutes to an hours time. The very slowiate of reaction at ordinary temperatures, say 20 C. to 25 C., is of particular value in the use and application of the composition. At such ordinary temperatures, the composition is stable for several days time. Consequently, the oxalic acid may be mixed with the glycidyl ether and it is not necessary immediately to apply the composition for the purpose intended such as pro- 70 tective coatings, molding materials and the like. Upon application of heat to the composition, it is rapidly converted to the reacted product.

The compositions of the invention are particing in an organic solvent and applying thesolution to a surface with subsequent curing of the film of resin-forming material. Various solvents are suitable for this purpose such'as lower saturated ketones like acetone, methyl ethyl ketone, methyl isobutyl ketone, methyl hexyl ketone, cyclohexanone, methyl cyclohexanone, etc.;esters like ethyl acetate, isopropyl acetate, butyl acetate; isoamyl acetate, etc.; and monoalkyl ethers of ethylene glycol like methyl, ethyl or butyl ethers. Preferably such solvents have a boiling point below 175C. If desired, other materials like lower aromatic hydrocarbons such as benzene, toluene and/or xylene may be used in combination with the oxygen-containing compounds for the purpose of cheapening the cost of the solvent.

The solutions of the composition of the invention are applied for coating surfaces needed to be protected by brushing, spraying and the like. The amount of solvent contained in the solution may b varied to suit the particular need. Ordinarily, the solution will contain about 5% to 60% of the composition of the invention. The solution is applied to the surface to be coated, and either the solvent is first allowed to evaporate, after whicn heat is applied by circulating hot air or by use of infra-red lamps, or the heating is effected with simultaneous removal of solvent and curing.

The coated surfaces containing a film of the cured composition have very desirable properties and this is especially true when the epoxy ether used in the composition is a glycidyl ether of a dihydrio phenol such as Resin A, for example. When cured, the resulting film is resistant to attack by acids such as 50% sulfuric acid. The film is remarkably resistant to the action of alkalis as distinguished from most filmforming materials such as unsaturated fatty oils and oil-modified alkyds. Thus, it may be boiled in 5% aqueous sodium hydroxide without harm.

The following examples are given for the purpose of illustrating use of the composition of the invention as surface coating materials:

Example I A composition was prepared for the purpose of testing oxalic acid as a curing agent when a surface coating film was prepared from the composition. A clear varnish was prepared by dissolving an equal part by weight of Resin Ain methyl ethyl ketone. To the solution was added 8.3% of oxalic acid dihydrate based on the weight of the resin. The solution was spread on a glass panel with the aid of a doctor blade and dried at room temperature for an hours time during which the solvent evaporated. The coated panel was then baked for 30 minutes time at 150 C. A smooth film of about 0.001 inch thick was obtained which was very hard and tough. The hardness and toughness was observed in the following manner:

A film is considered .hard when it is not scratchable with a thumbnail, fairly hard when only slightly scratchable, and soft when a deep scratch is readily made. A film is considered tough when a long, coherent ribbon may be removed by a knife-point being pushed in the film as a plow, and when theresistance to the motion of the knife-point is considerable. A film is considered brittle when a knife-point, moved as a plow, produces a shower of chips. .Jn order to be satisfactory as a surface-covering film, it

ularly useful for protective coatings by dissolvis not only necessary that the cured resin be 7 hard so as to-resist wear and abrasion, but that it'also be tough, rather than brittle, so as to have physical strength necessary for resistance to strain and shock.

For purposes of comparison, a cured film was for methyl ethyl ketone :in order to obtain a homogeneous solution; 10% of succinic acid based on the weight of resin was used. The resulting film was also unsatisfactory by being soft and brittle. r

. Example 11 A solution; consisting of equal parts of Resin A in methyl, ethyl ketone was prepared. To the [solution was added 10.9% of oxalic acid dihydrate based on the weight of resin. The mixture was warmedto assist dissolving the acid.

A cured film was formed by spreading the composition on a glass panel and baking for 30 minutes, at 150 C as described in Example I.

The-resulting film was harder and tougher. than that formed when the les'seramount (8.3%) of oxalic acid was-used. Moreover, upon preparing" another film from the composition containing 10.9%, oxalic acid dihydrate with curing effected by baking for only-l5 minutes at l50 C., it was found that this film had cured to a hard, tough material. I v I I Example In Another panel was prepared from the compo- Y sition described in- Example I wherein oxalic acid was used, the curing ,being effected by baking for '30 minutes at 150 C. The panel coated with the hard, tough film was placed in the openair so as toface southerly. Examination after a months exposure to the weather showed the film to be still smooth and hard with-no measurable loss of toughness. I

' Example IV A number of panelswere' prepared with coatings obtained.- from a composition containing equal parts of Res to which had beenadded 8% of oxalic acid dihydrate with curing of the film for 30 minutes at 150 C.

The cured films were unchanged after immerslon forl8 hours in water at 25 C., or for onehalf hour in lubricating oil at 100 C. Spot tests with the following reagents also left the films unchangedq minutes withtoluene, 30 minutes with 2% acetic acid, or 30 minutes with 2% sodium hydroxide. Thefilms had a Sward hardness of 43 and a .Taber 100 cycles.

A in methyl ethyl ketone abrasion of 2.9 mg. perv the hiding power of the particular pigment, about 5% to 200% pigment based on the weight of the glycidyl ether may be used in the enamels. Best results in preparing the enamels are obtained by grinding the pigment with a portion of thesolvent and epoxy ether, and then adding the remainder of the solvent and epoxy ether after the grinding operation. The enamel is ready for application upon addition of the curing agent, oxalic acid.

The enamel films obtained from-the composition of the invention for use as protective coatings have very desirable properties. They have a v flat finish which is particularly useful. Moreover, the cured films are very resistant against yellow- I ing produced by prolonged heating.

Aliphatic diamines are useful agents for efiect- I ing the curing of the glycidyl ethers used in the compositions of the present invention. However, the films cured with the aid of diamines, although ,hard and tough, are subject to marked discolor! ation. The superiority of films cured with oxalic acid in this respect is'evidentfrom the following results. 1

, Example V I An enamel base wasprepared containing 30.8%

' v by weight of Resin A, 30.8% titanium dioxide pigethylene glycol. The curing agents indicated in the table below were added to portionsof the" ment and 38.4% of the monomethyl ether of enamel base, the percentage being based on the weightof resin. Films of the enamels, were applied to the surface of steel panels. After dry-., ing forabout an hour, the films were cured by baking at 150 C. for 30 minutes. A second coat.

was applied in the same manner.

The tendency of the cured enamel films to yellow was tested by heating for 24 hours at 150? C. with observations of the change in color. In I I the table below, the color scale was such that the numeral 0 indicates the film was pure white and the numeral 5 indicates a light ivory color, while intermediate numerals have reference to uniform graded variations therebetween.

' I Color alter Color after Curing Agent Baking 24 I I m curing hours Oxalic acid dihydmeuu-njuua'. o o 4 g Diethylene triamine 2 5 When used as film-forming agents for protec I tive coatingathe composition may have various other materials incorporated therewith besides solvents such as pigments and other resins; Thus pigments like titaniumoxidajantimony crude, carbon black, chrome yellow, zinc oxide, para red, and the like, may be used. Depending upon With either varnishes or enamels containing the compositions of the invention, thick layers of the film-forming material may be applied to a surface. Curing completely'therethrough is attained because the conversion to an insoluble film is not dependent upon contact with air. This fact also makes the compositions valuable in manufacture of laminates. wherein the laminae are cloth, paper, glass-cloth and the like. Such laminae are impregnated with the compo-. sition which is ordinarily dissolved in a volatile solvent'like acetone. After drying, and, if desired, partial curing, the impregnated sheets are stacked and the cure completedin a press using suflicient pressure to form a homogeneous and coherent. massfor the resin-forming material such as 200' to lOOQor more pounds per square inch. I i

' The new compositions possess a peculiar and I unexpected property making them f particularly suitable forv molding operations. Most-resin- I forming materials contract in volume during cur- 2,ooo,449

ing thereof. In contrast, the compositions of the invention tend to expand during curing. Consequently, upon manufacturing molded articles I Example VI An enamel base was prepared of the following composition by weight:

To the-base was added 8% oxalic acid dihydrate as a 50% solution inthe monomethyl ether. of

Per cent Resin A 26.8 Titanium dioxide p'igment 26.8

Methyl ethyl ketone 18.1 Monomethyl ether of ethylene glycol acetate 15.1 Xylene; -1 13.2

10 Example .VIII

An enamel base of the following composition by weight was prepared:

Per cent Resin A- 39.8 Chrome yellow pigment 26.5 Monobutyl ether of ethylene glycol 17.4 Xylene 16.3

A 50% solution of oxalic acid dihydrate in monomethyl ether of ethylene glycol was added as ouring agent in amount of 8% acid based on the weight of Resin A. The enamel was flowed out on a steel panel. allowed to dry for an hour. and then baked for 30 minutes at 150 C. The cured film was a hard, fiat, yellow material.

Example IX The base of the enamel was of the following composition by weight:

Per cent Resin A 49.8 Carbon black pigment 4.1 Monobutyl ether-"of ethylene ,glycol 23.8 Xylene 22.3

The curing agent added to the enamel base was 18% of oxalic acid'dihydra'te as a 50%- solution in monomethyl ether of ethylene glycol, the per cent of acid beingbased ontheweight of Resin A. The enamel was flowed out on a steel panel,

allowed to dry for an hour, and then baked for 30 ethylenaglycoL-the amount of acid being based on the Weight of Resin A in the composition. The

' enamel was then: diluted with the same solvent 7 mixture as in the base to a viscosity of 15 seconds measured 'withaglass cup like the Ford viscosity cup. Theenamel was flowed out on a steel paneLLallowed to dry for an hour and then baked at I50 C. for 30 minutesu The resulting white film was hard and tough with a flat' finish.

Upon exposure to ultraviolet light from a General Electric AH5- mercury arc lamp at a distance of 28 cm. for 15 days, there was'only barely perceptible darkening of the film.

Example VII The enamel base had the following composition by weight:

Per cent Resin A 21.9 Para red (light shade) pigment 21.0 Methyl ethyl ketone--. 21.0 n-Butyl ac 18.5 Xylene 18.5

Oxalic acid dihydrate as a solution in the monomethyl ether of ethylene glycol was added to the extent of 8% acid based on the weight of Resin A after which the enamel was diluted with the same solvent mixture as in the base to a viscosity of 15 seconds measured with a glass cup like the Ford viscosity cup. The enamel was flowed out on a steel panel, allowed to dry for an hour, and then baked at 150 C. for 30 minutes. The resulting hard film had an excellent flat red finish. The darkening was only just perceptible upon exposing the film to ultraviolet light from a General Electric AH5 mercury lamp for 10 days at a distance of 28 cm.

minutes-at 150? C. The'resulting film was-hard 1 and tough; and had a semi-glossy black finish.

ITclaim as my invention:

1. A composition of matter comprising an ether of the class consisting of a glycidyl ether of a dihydric phenol and a' glycidyl etherofa polyhydric-alcohoL'and 5% to 300% ofthe equivalent amount of oxalic"ac i d,.said ether having a 1,2- epoxy equivalency greater than one 'andcontaining no other reactive functional groups than epoxy andhydroxyl groups.

2. A composition of matter comprising a glycidyl ether of a dihydric phenol having a 1,2- epoxy equivalency greater than one, and"6 0% to 170% of the equivalent amount of oxalic acid,

said ether containing no other reactive. functional groups than epoxy and hydroxyl groups.

' 3. A- composition of matter comprising a glycidyl ether of'bis-(4-hydroxyphenyl) -2,2-propane having a 1.2-epoxy"equiv'alency of greater thari one, and 60% to 170% of the equivalent-amount of oxalic acid.

4. A heat curable enamel comprising a fluid mixture of a lower aliphatic ketone, a metal oxide pigment, a glycidyl ether of bis-(4-hydroxyphenyl)-2,2-propane having a 1,2-epoxy equivalency greater than one, and oxalic acid in amount of to of the equivalent amount of said glycidyl ether.

5. A composition of matter comprising a glycidyl ether of glycerol having a 1,2-epoxy equivalency greater than one and 60% to of the equivalent amount of oxalic acid.

6. A process for producing a resinous product which comprises heating and reacting 60% to 170% of the equivalent amount of oxalic acid with a glycidyl ether having a 1,2-epoxy equivalency greater than 1.0 which is of the formula ll wherein R represents the divalent hydrocarbon radical of a dihydric phenol and n is an integer. 7. The resinous product obtained by the process defined in claim 6.

8. A process forproducing a resinous product 5 which comprises heating at 125 C. to 175 C. a

glycidyl ether of bis-(4'-hydroxyphenyl) -2,2-propane having a1,2-epoxy equivalency greater than 2399314 12 one with 110%to 160% of the equivalent amount of oxalic acid. 1

11. The resinous product obtained by the process defined in claim 10.

THEODORE F. BRADLEY.

REFERENCES CITED .The following references are 01 record in he 10 file of this patent:

UNITED STATES PATENTS Number Name Date 2,324,483 Caston July 20, 1943 Evans Apr. 30, 1946 

1. A COMPOSITION OF MATTER COMPRISING AN ETHER OF THE CLASS CONSISTING OF A GLYCIDYL ETHER OF A DIHYDRIC PHENOL AND A GLYCIDYL ETHER OF A POLYHYDRIC ALCOHOL, AND 5% TO 300% OF THE EQUIVALENT AMOUNT OF OXALIC ACID, SAID ETHER HAVING A 1,2EPOXY EQUIVALENCY GREATER THAN ONE AND CONTAINING NO OTHER REACTIVE FUNCTIONAL GROUPS THAN EPOXY AND HYDROXYL GROUPS. 